# Performance analysis of a three-dimensional micromixer with baffles using a flexible physics-informed neural network

**Authors:** Meraj Hassanzadeh, Ehsan Ghaderi, Mohamad Ali Bijarchi

PMC · DOI: 10.1038/s41598-026-40254-7 · Scientific Reports · 2026-02-21

## TL;DR

Researchers developed a new neural network to efficiently model and optimize complex 3D micromixers with baffles, achieving high accuracy and faster training.

## Contribution

A novel flexible physics-informed neural network (FlexPINN) is introduced for 3D micromixer analysis with improved efficiency and accuracy.

## Key findings

- FlexPINN reduces training time by ~35% using transfer learning for new baffle shapes.
- Rectangular baffles in a staggered configuration at Re=40 achieved peak mixing efficiency of 1.63.
- FlexPINN predictions showed <3.25% error compared to CFD simulations for micromixer performance.

## Abstract

This study introduces a Flexible Physics-Informed Neural Network (FlexPINN) to overcome the limitations of standard PINNs in modeling fully three-dimensional, geometrically complex micromixers with internal baffles. The mesh-free framework integrates parallel-network architecture, first-order dimensionless governing equations, adaptive loss weighting, and a novel global conservation penalty to prevent trivial solutions and ensure robust convergence. Employing transfer learning reduces the training time for new baffle shapes by ~ 35%, requiring approximately 3.5 h versus 5.5 h for a base case on a single GPU. Validated against conventional Computational Fluid Dynamics, FlexPINN achieves high-fidelity predictions, with maximum relative errors of 3.25% for the pressure drop coefficient and 2.86% for the mixing index. A comprehensive parametric study evaluates three baffle shapes (rectangular, elliptical, triangular) across four configurations and Reynolds numbers (Re = 5, 20, 40, 80). Results demonstrate that rectangular baffles in a double-unit, staggered configuration (C) at Re = 40 yield the peak mixing efficiency of 1.63, significantly outperforming other designs. This work successfully bridges a critical gap in PINN applications by providing a validated, efficient tool for the analysis and optimization of intricate 3D passive micromixers.

## Full-text entities

- **Chemicals:** PINN (-)

## Full text

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## Figures

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## References

2 references — full list in the complete paper: https://tomesphere.com/paper/PMC13022295/full.md

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Source: https://tomesphere.com/paper/PMC13022295